WO2021128473A1

WO2021128473A1 - Active free radical polymerization method for vinyl-based monomers under near-infrared photothermal conversion

Info

Publication number: WO2021128473A1
Application number: PCT/CN2020/070786
Authority: WO
Inventors: 张丽芬; 高群; 程振平; 涂凯; 李海辉; 姚澜; 朱秀林
Original assignee: 苏州大学
Priority date: 2019-12-27
Filing date: 2020-01-08
Publication date: 2021-07-01
Also published as: US11958919B2; CN111040060B; AU2020331561A1; US20220112316A1; CN111040060A; AU2020331561B2

Abstract

An active free radical polymerization method for vinyl-based monomers under near-infrared photothermal conversion. A reaction container is irradiated by adopting near-infrared light with the wavelength of 750-850 nm, the adopted reaction container is provided with a first cavity and a second cavity which are not communicated with each other, an organic solution of a keto cyanine-based near-infrared photoresponsive dye is comprised in the first cavity, a sealed reaction bottle for containing a reaction liquid is placed in the second cavity; the reaction liquid comprises two or more selected from the vinyl-based monomers, an ATRP initiator, an ATRP ligand, an ATRP catalyst, an RAFT reagent, a thermal initiator and an additive, and an organic solvent; near-infrared light is irradiated into the second cavity from the first cavity; and the near-infrared photoresponsive dye converts the near-infrared light nto heat energy, and the reaction container is heated to 50-100℃, so that the monomers in the reaction liquid are polymerized to obtain a polymer having controllable molecular weight and controllable molecular weight distribution.

Description

"Living" radical polymerization method of vinyl monomers under near-infrared photothermal conversion

Technical field

The invention relates to the technical field of polymer preparation, in particular to a "living" radical polymerization method under near-infrared photothermal conversion of vinyl monomers.

Background technique

In "living"/controllable free radical polymerization (LRP), polymerization can be controlled by controlling reaction conditions such as temperature, light, mechanical force, applied voltage, and chemical redox. According to the wavelength of light, the light source used for photopolymerization can be roughly divided into ultraviolet light (UV, <400nm, ~6eV), visible light (vis, 400-700nm, ~2eV) and near-infrared light (NIR, 670-1100nm, ~1.5eV) and so on. In recent years, scientific researchers have used ultraviolet light, visible light and other light sources to develop a variety of light-controlled LRP technologies, such as initiation-transfer-termination polymerization (Iniferter), nitroxide stable radical polymerization (NMP), atom transfer radical polymerization (ATRP) ), reversible complex polymerization in the presence of iodine (RCMP), bromoiodide conversion living radical polymerization, light-induced electron transfer-reversible addition-fragmentation chain transfer polymerization (PET-RAFT), etc. However, through investigation, it can be found that most light-controlled LRPs are carried out under blue wavelength or shorter wavelength UV. This short-wavelength light source has high energy and is prone to side reactions; at the same time, short-wavelength light will be refracted during the penetration process. , Scattering, resulting in insufficient penetration ability. Near-infrared (NIR) light sources are characterized by long wavelengths and low energy. According to relevant theoretical calculations, the depth of penetration of near-infrared light into tissues can reach 7-14 cm, and the fluorescent background of living organisms can be almost completely eliminated. However, polymerization controlled by near-infrared light has various obstacles. For example, compared with UV and visible light, NIR energy is lower, and it is difficult to effectively stimulate chemical reactions under normal conditions. So far, the literature on LRP controlled by near-infrared light is very limited. For example, Boyer et al. used bacterial chlorophyll a as a catalyst for PET-RAFT polymerization to obtain polymers with controllable molecular weight and narrow molecular weight distribution. However, this catalyst is difficult to synthesize and expensive, which is not conducive to large-scale production.

Summary of the invention

In order to solve the above technical problems, the purpose of the present invention is to provide a "living" free radical polymerization method under near-infrared photothermal conversion of vinyl monomers, which utilizes near-infrared photo-responsive substances through photothermal conversion, that is, under light irradiation The heat energy generated under the polymerization reaction is used for the energy required for the "living"/controllable free radical polymerization. The method of the present invention has mild conditions, a wide range of monomers, and the adopted near-infrared dye solution has stable photothermal properties and can be recycled for a long time. use.

To solve the above technical problems, the present invention adopts the following technical solutions:

The purpose of the present invention is to provide a "living" radical polymerization method under near-infrared photothermal conversion of vinyl monomers. The reaction vessel is irradiated with near-infrared light with a wavelength of 750-850nm, and the reaction vessel used has mutual A first cavity and a second cavity that are not connected, wherein the organic solution of the near-infrared light-responsive dye is placed in the first cavity, and the second cavity is used to place a closed reaction flask containing the reaction liquid, The reaction flask is filled with protective gas; the near-infrared light is irradiated into the near-infrared light-responsive dye solution in the first cavity to convert the near-infrared light into heat, and the reaction flask in the second cavity is heated to the polymerization site A variety of "living" radical polymerization techniques for vinyl monomers are constructed at a temperature of 50-100°C according to the composition of the reaction solution to obtain polymers represented by formulas (4)-(6);

The near-infrared light-responsive dyes include the croton acid cyanine compounds represented by formulas (1)-(3):

Wherein, n ₁ and n ₂ are independently selected from 1-10;

The reaction solution includes vinyl monomers, organic solvents, ATRP initiators, ATRP ligands and ATRP catalysts; or

The reaction liquid includes vinyl monomers, organic solvents, RAFT reagents and thermal initiators; or

The reaction liquid includes vinyl monomers, organic solvents, ATRP initiators and additives; the additives include organic amines and/or iodine-containing compounds;

The structural formulas of the polymers represented by formulas (4)-(6) are as follows:

Wherein, m ₁ , m ₂ and m ₃ are independently selected from 10-300;

R ₁ , R ₁ ′ and R ₁ ″ are each independently selected from isobutyl cyano group, 4-cyanovaleric acid group, 2-phenylacetate group or 2-isobutyric acid ethyl group;

R ₂ , R ₂ ′ and R ₂ ″ are each independently selected from hydrogen or methyl;

R ₃ , R ₃ ′ and R ₃ ″ are each independently selected from phenyl, 2-naphthyl, bromine, chlorine or iodine;

R _{4 is} selected from methyl, butyl, polyethylene glycol monomethyl ether, hydroxyethyl, hydroxypropyl or N,N-dimethylaminoethyl;

R _{5 is} selected from hydrogen, methyl, ethyl or hydroxymethyl;

R _{6 is} selected from hydrogen, methyl, ethyl or hydroxymethyl.

Further, "living" radical polymerization includes atom transfer radical polymerization (ATRP), bromoiodine conversion "living" radical polymerization, and reversible addition-fragmentation chain transfer polymerization (RAFT). When the reaction liquid includes vinyl monomers, organic solvents, ATRP initiators, ATRP ligands and ATRP catalysts, vinyl monomers undergo ATRP polymerization. When the reaction liquid includes vinyl monomers, organic solvents, RAFT reagents and In the case of thermal initiators, the vinyl monomers undergo RAFT polymerization. When the reaction solution includes vinyl monomers, organic solvents, ATRP initiators and additives, the vinyl monomers undergo bromine-iodine conversion "living" radical polymerization.

Further, in the organic solution of the near-infrared light-responsive dye, the concentration of the near-infrared light-responsive dye is 1.0-10.0 mg/mL, and the power of the near-infrared light is 0.05-1.0 W/cm ² . Preferably, it is 0.1-0.3 W/cm ² .

Further, the vinyl monomers are methyl acrylate, methyl methacrylate (MMA), butyl acrylate, butyl methacrylate, polyethylene glycol monomethyl ether acrylate, and polyethylene glycol methacrylate. Methyl ether ester, hydroxyethyl acrylate, hydroxyethyl methacrylate, hydroxypropyl acrylate, hydroxypropyl methacrylate, N,N-dimethylaminoethyl methacrylate, glycidyl methacrylate, styrene , N,N-dimethylacrylamide, N,N-diethylacrylamide, N-dihydroxyethylacrylamide.

Further, the ATRP initiator is one or more of ethyl 2-bromophenylacetate, ethyl 2-bromoisobutyrate and 2-iodo-2-methylpropionitrile; the ATRP ligand is bipyridine, One or more of pentamethyldivinyltriamine, hexamethyltrivinyltetraamine and triphenylphosphine; ATRP catalyst is one or more of CuBr, CuCl, FeBr ₂ and FeCl ₂ .

Further, the RAFT reagent is isobutyronitrile dithionaphthoate or 4-cyano-4-(thiobenzoyl)valeric acid; the thermal initiator is azobisisobutyronitrile and/or benzyl peroxide Acyl.

Further, when R ₁ is isobutylcyano group, the RAFT reagent is isobutyronitrile dithionaphthoate (CPDN); when R ₁ is 4-cyanovaleric acid group, the RAFT reagent is 4-cyano-4 -(Thiobenzoyl)valeric acid (CPADB). Preferably, CPADB is selected.

Further, the additive is one or more of NaI, KI, triethylamine, triethanolamine and tetrabutylammonium iodide.

Further, the organic solvent is one or more of toluene, acetone, ethanol, methanol, N,N-dimethylformamide and dimethyl sulfoxide.

Further, the molar ratio of vinyl monomer, RAFT reagent and thermal initiator is 50-1000:2:1-0.5; the molar ratio of vinyl monomer, ATRP initiator, ATRP catalyst and ATRP ligand is 50 -1000:1:0.01-1.5:0.3-4.5; the molar ratio of vinyl monomer, ATRP initiator and additives is 50-1000:1:1-10. Preferably, the molar ratio of vinyl monomer, RAFT reagent and thermal initiator is 300-500:2:1; the molar ratio of vinyl monomer, ATRP initiator, ATRP catalyst and ATRP ligand is 100-500 :1:0.05-1:0.3-3; the molar ratio of vinyl monomer, ATRP initiator and additives is 50-500:1:1-2.

Further, the concentration of the vinyl monomer in the reaction solution is 1.0-8.0 mol/L, preferably 1.0-4.0 mol/L.

Further, the reaction time is 1-20h.

Further, the first cavity surrounds the outside of the second cavity, and the device for generating near-infrared light surrounds the outside of the first cavity.

Further, the reaction container is a glass jacketed reaction flask, and the second cavity provides a water bath environment for the sealed reaction flask.

Further, the solvent of the organic solution of the near-infrared light-responsive dye is toluene.

Further, the light source used for illumination of the present invention is a near-infrared LED lamp. Preferably, the light wavelength is 810 nm.

The present invention also discloses a polymerization reaction device under near-infrared photothermal conversion, which comprises a reaction container, the reaction container is used for receiving near-infrared light irradiation, and the reaction container has a first cavity and a second cavity that are not connected to each other. The first cavity contains the organic solution of the near-infrared light-responsive dye, and the second cavity is equipped with a reaction flask containing the reaction liquid; the near-infrared light is irradiated into the first cavity, and the near-infrared light-responsive dye is near infrared The light is converted into heat energy, and the reaction liquid in the second cavity is heated to 50-100°C.

Further, the first cavity surrounds the outside of the second cavity, and the outside of the first cavity is surrounded by an illumination unit, and the illumination unit is used to emit near-infrared light.

With the above solution, the present invention has at least the following advantages:

The present invention is based on a polymerization reaction device under near-infrared photothermal conversion, which uses near-infrared photo-responsive dyes to convert near-infrared light into heat, and the generated heat heats the reaction vessel, and uses near-infrared photothermal conversion to generate heat energy required for polymerization, avoiding This solves the problems of uneven light irradiation and low penetration of short-wavelength light. The method of the invention has mild conditions, a wide range of monomers, and the adopted near-infrared dye solution has stable photothermal properties and can be recycled for a long time. By adopting the preparation method of the present invention, the molecular weight of the polymer increases linearly with the increase of the conversion rate, and the molecular weight distribution is also narrow (M _w /M _n <1.20), which conforms to the characteristics of "living" radical polymerization.

The above description is only an overview of the technical solution of the present invention. In order to understand the technical means of the present invention more clearly and implement it in accordance with the content of the description, the preferred embodiments of the present invention will be described in detail below in conjunction with the accompanying drawings.

Description of the drawings

Figure 1 is the heating test results of different concentrations of crotonic acid cyanine near-infrared dyes under near-infrared light (λ=810nm, 100mW/cm ^{2 );}

Figure 2 is the heating test results of near-infrared dyes with a concentration of 6.4mg/mL under near-infrared light (λ=810nm) at different powers;

^{Figure 3 is the 1} H NMR test result of the polymer PMMA in Example 2;

4 is a polymerization kinetics diagram and GPC flow curve during the preparation process of polymer PMMA in Example 2;

Figure 5 shows the chain extension of the polymer PMMA in Example 2;

^{Figure 6 is the 1} H NMR test result of the polymer PDMA in Example 3;

^{Figure 7 is the 1} H NMR test result of the polymer PGMA in Example 4;

^{8 is the 1} H NMR test result of the polymer PMA in Example 5;

^{Figure 9 is the 1} H NMR test result of the polymer PS in Example 6;

^{Figure 10 is the 1} H NMR test result of the polymer PMMA in Example 7;

^{FIG. 11 is the 1} H NMR test result of the polymer PMMA in Example 8. FIG.

Detailed ways

The specific implementation of the present invention will be described in further detail below in conjunction with the accompanying drawings and embodiments. The following examples are used to illustrate the present invention, but not to limit the scope of the present invention.

In the following embodiments of the present invention, the used raw material MMA needs to be passed through a neutral alumina column to remove the polymerization inhibitor, and then placed in the upper layer of the refrigerator for storage. The ketone acid cyanine near-infrared dyes were synthesized in the laboratory according to the methods in the literature "Dyes Pigments, 2008, 78, 60." and "J. Am. Chem. Soc., 2017, 139, 11333.". Other reagents can be used directly after they are obtained commercially.

In the present invention, the following test methods are used:

1. The number average molecular weight (M _{n, GPC} ) and molecular weight distribution (M _w /M _n ) of the obtained polymer are measured by TOSOH HLC-8320 gel permeation chromatography (GPC), which is equipped with a TOSOH refractive index detector. One guard column (4.6×20mm, TSKgel guard column SuperMP-N) and two test columns (4.6×150mm, TSKgelSupermultiporeHZ-N), the testable molecular weight ranges from 5×10 ² to 5×10 ⁵ g/mol. During the test, THF was used as the mobile phase, the temperature was 40°C, and the flow rate was 0.35 mL/min. The sample is drawn through the TOSOH autosampler for testing. When analyzing the data, the linear PMMA purchased from TOSOH is selected as the standard sample. The preparation process of the sample for testing GPC is as follows: take 20μL of polymer mixed solution, freeze-dry, remove the solvent, then dissolve the polymer with THF, pass the polymer solution through a small column of neutral alumina and filter with 0.45μm Head the syringe, and finally inject the pure polymer solution into the test bottle.

2. The NMR spectra of the obtained product and the polymer were measured by Bruker 300MHz nuclear magnetic resonance instrument, using CDCl ₃ as the deuterated reagent, tested at room temperature (25° C.), and tetramethylsilane (TMS) as the internal standard.

3. UV-vis is measured by Shimadzu UV-2600 ultraviolet-visible spectrophotometer, with toluene as the solvent.

Example 1 Study on the photothermal conversion efficiency of ketocyanine-based near-infrared dyes

Dissolve the ketone acid cyanine dye shown in formula (1) in the instruction manual in 7mL of toluene, prepare different concentrations (2.0mg/mL, 5.0mg/mL, 6.0mg/mL) and add them to the glass jacketed reaction flask in sequence Place the glass jacketed reaction flask in the near-infrared ring light source (λ=810nm), and use the infrared imager of Xinsite HT-18 to test different concentrations of dyes. Minute heating situation.

Figure 1 shows the different concentrations (0mg/mL, 2.0mg/mL, 5.0mg/mL, 6.0mg/mL) of crotonic acid cyanine near-infrared dyes (shown in formula (1)) under near-infrared light (λ=810nm) ,100mW/cm ² ) heating test results.

According to the above method of measuring the concentration of 6.4mg / mL croconium cyanine dyes of different power ^{(0.10W / cm 2, 0.15W /} cm 2, 0.22W / cm 2, 0.34W / cm 2) the near infrared light ( λ=810nm) the temperature rise under irradiation.

Figure 2 is the temperature rise test results of 6.4 mg/mL ketocyanine dyes under near-infrared light at different powers.

Example 2 Preparation of polymethyl methacrylate by reversible-addition fragmentation chain transfer polymerization

Dissolve 35.0 mg of the ketocyanine dye (1) into 7.0 mL of toluene, and then transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows: the polymerization system monomer methyl methacrylate (MMA), RAFT reagent 4-cyano-4-(thiobenzoyl)pentanoic acid (CPADB) and the thermal initiator azo Diisobutyronitrile (AIBN) molar ratio [MMA] ₀ /[CPADB] ₀ /[AIBN] ₀ ＝500:2:1, respectively MMA (0.20mL, 1.88mmol), CPADB (2.10mg, 7.53×10 ^-3 mmol), AIBN (0.62mg, 3.76×10 ^-3 mmol), toluene (0.30mL), add a 2mL clean ampoule, put a clean stir bar. The mixed solution is a pink homogeneous solution. Place the ampoule in liquid nitrogen to freeze the solution, and then pump for 20-30 seconds, then add argon to thaw and dissolve at room temperature, and then freeze and pump. Thaw and inflate, repeat this process three times, and seal the ampoule. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacket reaction flask is placed on the magnetic stirrer, and the constant temperature of the photothermal conversion at this time is 59.8°C. After the reaction reaches a certain time, the temperature of the ampoule is lowered, the tube is broken, and 20 μL of polymer (PMMA) solution is dissolved in CDCl ₃ with a pipette to perform ¹ H NMR test, and the conversion rate is calculated. The structural formula of the product polymer PMMA prepared by the above method is as follows:

Under the above reaction conditions, the monomer conversion rate under different reaction times was measured, and the polymerization kinetics diagram as shown in FIG. 4 was obtained. It can be seen from Figure 4(a) that from 0 to 7 hours, ln([M] ₀ /[M]) conforms to first-order kinetics with time. It can be seen from Figure 4(b) that the polymer With the increase of the conversion rate, the molecular weight of Mw shows a linear growth trend, and the molecular weight distribution is also narrower (M _w /M _n <1.20). The molecular weight obtained by GPC is closer to the theoretical molecular weight, which also indicates that the polymer has a higher degree of terminal functionalization. The polymerization kinetics showed that using CPADB as the chain transfer reagent, the RAFT polymerization of MMA initiated under the irradiation of a near-infrared ring light source conformed to the characteristics of "living" polymerization. In Figure 4(c), from right to left, the curves correspond to the polymerization products numbered 1, 2, 3, 4, 5, 6, and 7 in Table 1. It can be seen from Figure 4(c) that the polymer The change in the molecular weight of the polymer from a longer outflow time to a shorter outflow time indicates the process of the polymer's molecular weight from small to large.

Table 1 shows the test results of product polymerization under different polymerization times. The monomer conversion rate (Conv.%) is measured by the NMR spectrometer, R represents [MMA] ₀ /[CPADB] ₀ /[AIBN] ₀ ; M _n,th Represents the molecular weight calculated according to the formula M _n,th =M _CPADB +[Monomer] ₀ /[CPADB] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w /M _n represents The molecular weight distribution.

Table 1: Test results of product polymerization under different polymerization times

Select PMMA with a molecular weight of 12300g/mol and a molecular weight distribution of 1.10 (curve a in Figure 5) as a macromolecular RAFT reagent for chain extension for one hour of polymerization, and use [MMA] ₀ :[PMMA] with monomers and initiators ₀ : [AIBN] ₀ = 600:1:0.5 mixing in the ratio, processing as described above, ^{after 3.5 hours under near-infrared light (λ=810nm, 100mW/cm 2} ), post-processing in the same way to obtain the molecular weight It is a polymer with a molecular weight distribution of 21,600 g/mol and a molecular weight distribution of 1.10 (curve b in Figure 5), which proves that the synthesized polymer has "active" characteristics.

In the present invention, the polymerized monomers used can also be selected from other monomers other than MMA, such as methyl acrylate, butyl (meth)acrylate, polyethylene glycol monomethyl ether (meth)acrylate, (meth) Hydroxyethyl acrylate and N,N-dimethylaminoethyl (meth)acrylate can also be used to obtain "living"/controllable polymers using the above-mentioned polymerization methods.

Example 3 Preparation of polymer poly-N,N-dimethylacrylamide (PDMA) by RAFT polymerization

Dissolve 35.0 mg of the near-infrared ketone acid cyanine dye represented by formula (1) in 7 mL of toluene, and transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion Heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows: the monomer N,N-dimethylacrylamide (DMA), the RAFT reagent CPADB and the water-soluble initiator azobiscyanovaleric acid (V-501) in the polymerization system Compared with [DMA] ₀ /[CPADB] ₀ /[V-501] ₀ =500/2/0.8, DMA (0.20mL, 1.80mmol), CPADB (1.17mg, 7.20×10 ^-3 mmol), V- 501 (0.48mg, 2.88×10 ^-3 mmol), toluene (0.30mL), add a 2mL clean ampoule, put a clean stir bar. Put the ampoule in liquid nitrogen to freeze the solution, and then pump for 20-30 seconds, then add argon, let it thaw and dissolve at room temperature, then freeze, pump, thaw and inflate. This process is repeated three times. Ampoule sealing tube. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacketed reaction flask is placed on the magnetic stirrer, at this time the temperature of the photothermal conversion is 60.0°C. After the reaction reaches a certain time, the ampoule is cooled down, the tube is broken, and 20 μL of polymer (PDMA) solution is dissolved in CDCl ₃ with a pipette to perform ¹ H NMR test, and the conversion rate is calculated. The structural formula of the product polymer PDMA prepared by the above method is as follows:

Table 2: Test results of product polymerization under different polymerization times

Table 2 shows the test results of the product polymerization under different polymerization times, R represents [DMA] ₀ /[CPADB] ₀ /[V-501] ₀ ; the monomer conversion rate (Conv.%) is calculated by NMR; M _{n, th} represents the molecular weight calculated according to the formula M _n,th =M _CPADB +[Monomer] ₀ /[CPADB] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w /M _n Indicates molecular weight distribution.

From the above polymerization results, it can be seen that the polymerization method of the present invention can also realize the "living" radical polymerization of N,N-dimethylacrylamide monomer, and has good controllability and polymerization speed.

Example 4 Preparation of polymer polyglycidyl methacrylate (PGMA) by RAFT polymerization

Dissolve 35.0 mg of the near-infrared ketone acid cyanine dye represented by formula (1) in 7 mL of toluene, and transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion Heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows, the polymerization system monomer glycidyl methacrylate (GMA), RAFT reagent isobutyronitrile dithionaphthoate (CPDN) and initiator AIBN molar ratio [GMA] ₀ / [CPDN] ₀ /[AIBN] ₀ =300/2/1, respectively, GMA (0.20mL, 1.50mmol), CPDN (2.70mg, 0.01mmol), AIBN (0.80mg, 5.00×10 ^-3 mmol), toluene (0.30mL), add to 2mL clean ampoule, put a clean stir bar. Put the ampoule in liquid nitrogen to freeze the solution, and then pump for 20-30 seconds, then add argon, let it thaw and dissolve at room temperature, then freeze, pump, thaw and inflate. This process is repeated three times. Ampoule sealing tube. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacketed reaction flask is placed on the magnetic stirrer, and the temperature of the photothermal conversion is 58.8℃. After the reaction reaches a certain time, the ampoule is cooled down, the tube is broken, and 20 μL of polymer (PGMA) solution is dissolved in CDCl ₃ with a pipette to perform ¹ H NMR test, and the conversion rate is calculated. The structural formula of the product polymer PGMA prepared by the above method is as follows:

Table 3: Test results of GMA monomer polymerization

Table 3 shows the test results of GMA monomer polymerization under the above conditions. R represents [GMA] ₀ /[CPDN] ₀ /[AIBN] ₀ ; the monomer conversion rate (Conv.%) is calculated by nuclear _{magnetism; M n,th} represents The molecular weight calculated according to the formula M _n,th =M _CPDN + [Monomer] ₀ /[CPDN] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w /M _n represents the molecular weight distributed.

From the above polymerization results, it can be seen that the polymerization method of the present invention can also carry out the "living" radical polymerization of glycidyl methacrylate monomer, and has good controllability and polymerization speed.

Example 5 Preparation of polymethyl acrylate (PMA) by RAFT

Dissolve 35.0 mg of the near-infrared ketone acid cyanine dye represented by formula (1) in 7 mL of toluene, and transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion Heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows, the polymerization system monomer methyl acrylate (MA), RAFT reagent CPDN and initiator AIBN mole ratio [MA] ₀ /[CPDN] ₀ /[AIBN] ₀ =300/2/ 1. Add MA (0.30mL, 3.31mmol), CPDN (5.97mg, 0.02mmol), AIBN (1.81mg, 0.01mmol), and toluene (0.20mL) respectively into 2mL clean ampoule, and put one capsule Clean stir bar. Put the ampoule in liquid nitrogen to freeze the solution, and then pump for 20-30 seconds, then add argon, let it thaw and dissolve at room temperature, then freeze, pump, thaw and inflate. This process is repeated three times. Ampoule sealing tube. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacketed reaction flask is placed on the magnetic stirrer, at this time the temperature of the photothermal conversion is 60.0°C. After the reaction reaches a certain time, the ampoule is cooled down, the tube is broken, and 20 μL of polymer (PGMA) solution is dissolved in CDCl ₃ with a pipette to perform ¹ H NMR test, and the conversion rate is calculated. The structural formula of the product polymer PMA prepared by the above method is as follows:

Table 4: Test results of MA monomer polymerization

Table 4 shows the test results of the MA monomer polymerization under the above polymerization conditions. R represents [MA] ₀ /[CPDN] ₀ /[AIBN] ₀ ; the monomer conversion rate (Conv.%) is calculated by nuclear _{magnetism; M n,th} Represents the molecular weight calculated according to the formula M _n,th =M _CPDN +[Monomer] ₀ /[CPDN] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w /M _n represents The molecular weight distribution.

From the above polymerization results, it can be seen that the polymerization method of the present invention can also "living" polymerization of methyl acrylate monomers, and has good controllability.

Example 6 Preparation of polystyrene (PS) by RAFT polymerization

Dissolve 35.0 mg of the near-infrared ketone acid cyanine dye represented by formula (1) in 7 mL of toluene, and transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion Heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows, the polymerization system monomer styrene (St), RAFT reagent CPDN and initiator AIBN mole ratio [St] ₀ /[CPDN] ₀ /[AIBN] ₀ ＝400/2/1 , Respectively add St (0.20mL, 1.71mmol), CPDN (2.40mg, 8.60×10 ^-3 mmol), AIBN (0.70mg, 4.26×10 ^-3 mmol), toluene (0.30mL) into 2mL clean ampoule Put a clean stirrer into the bottle. Put the ampoule in liquid nitrogen to freeze the solution, and then pump for 20-30 seconds, then add argon, let it thaw and dissolve at room temperature, then freeze, pump, thaw and inflate. This process is repeated three times. Ampoule sealing tube. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 300mW/cm ² ) , The glass jacketed reaction flask is placed on a magnetic stirrer, and the temperature of the light-to-heat conversion is 90.2°C. After the reaction reaches a certain time, the temperature of the ampoule is cooled, the tube is broken, and the conversion rate is measured by the gravimetric method. The structural formula of the product polymer PS prepared by the above method is as follows:

Table 5: Test results of St monomer polymerization

Table 5 shows the test results of St monomer polymerization under the above conditions, R represents [St] ₀ /[CPDN] ₀ /[AIBN] ₀ ; the monomer conversion rate (Conv.%) is calculated by the gravimetric method; M _n,th Represents the molecular weight calculated according to the formula M _n,th =M _CPDN +[Monomer] ₀ /[CPDN] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w /M _n represents The molecular weight distribution.

From the above polymerization results, it can be seen that the polymerization method of the present invention can also "living" free radical polymerization of styrene monomer, and has good controllability.

Example 7 Preparation of polymer PMMA by atom transfer radical polymerization (ATRP)

Dissolve 35.0 mg of the near-infrared ketone acid cyanine dye represented by formula (1) in 7 mL of toluene, and transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion Heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows: Use ethyl 2-bromoisobutyrate (EBiB) as the ATRP initiator to initiate the polymerization of monomer MMA. In the polymerization system, monomer MMA, initiator EBiB, catalyst CuBr and ligand bipyridine are used. (bpy) The molar ratio [MMA] ₀ /[EBiB] ₀ /[CuBr] ₀ /[bpy] ₀ ＝400/1/1/2, respectively MMA (0.25mL, 2.35mmol), EBiB (3.40μL, 5.87×10 ^-3 mmol), CuBr (3.40mg, 5.87×10 ^-3 mmol), bpy (7.3mg, 1.17×10 ^-2 mmol), toluene (0.25mL), add to 2mL clean ampoule, put Add a clean blender. In addition, several sets of parallel experiments were performed, the same monomers, catalysts and ligands were selected, and the ATRP initiator was replaced with 2-iodo-2-methylpropionitrile (CP-I), and the molar ratio [MMA] ₀ /[CP- I] ₀ /[CuBr] ₀ /[bpy] ₀ =200/1/1/2, MMA (0.25mL, 2.35mmol), CP-I (2.70μL, 1.17×10 ^-2 mmol), CuBr (3.40 mg, 1.17×10 ^-2 mmol), bpy (7.3 mg, 2.35×10 ^-2 mmol), toluene (0.25mL), add to 2mL clean ampoule, put a clean stir bar. Place the ampoule in liquid nitrogen to freeze the solution, then pump for 20-30 seconds, then add argon, let it thaw and dissolve at room temperature, then freeze, pump, thaw, and inflate. This process is repeated three times. The oxygen in the ampoule is exhausted. After deoxygenation, quickly move the ampoule to the nozzle of the spray gun, and seal the ampoule with an outer flame. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacketed reaction flask is placed on the magnetic stirrer, at this time the temperature of the photothermal conversion is 60.0°C. After the reaction reaches a certain time, the ampoule is cooled down, the tube is broken, and the weight method is adopted to calculate the monomer conversion rate. The structural formulas of the product polymer PMMA prepared by the above methods are as follows, and the ¹ H NMR test results are shown in Fig. 10a and b respectively:

Table 6: Test results of product polymerization under different initiators and different polymerization times

Table 6 shows the test results of product polymerization under different polymerization conditions, R represents [MMA] ₀ /[I] ₀ /[CuBr] ₀ /[bpy] ₀ ; the monomer conversion rate (Conv.%) is calculated by the weight method ;M _n,th represents the molecular weight calculated according to the formula M _n,th =M _I +[Monomer] ₀ /[I] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w / M _n represents the molecular weight distribution.

The results show that the polymer obtained by the ATRP method also has a controllable molecular weight and a narrow molecular weight distribution.

Example 8 Preparation of polymer PMMA by in-situ bromine-iodine conversion "living" radical polymerization

Dissolve 35.0 mg of the near-infrared ketone acid cyanine dye represented by formula (1) in 7 mL of toluene, and transfer it to the outer jacket of the glass jacketed reaction flask, which is the first cavity, and use it as a light-to-heat conversion Heat source. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. Among them, the preparation method of the reaction solution is as follows: monomer MMA, ATRP initiator 2-bromophenylacetate (EBPA), NaI and catalyst tetrabutylammonium iodide (BNI) mole ratio [MMA] ₀ /[EBPA] ₀ /[NaI] ₀ /[BNI] ₀ =800/8/9/9, respectively MMA (1mL, 9.4mmol), EBPA (17μL, 9.4×10 ^-2 mmol), NaI (15mg, 0.106mmol), Add BNI (37mg, 0.106mmol) to a 2mL clean ampoule, and put a clean stir bar. Place the ampoule in liquid nitrogen to freeze the solution, then pump for 20-30 seconds, then add argon, let it thaw and dissolve at room temperature, then freeze, pump, thaw, and inflate. This process is repeated three times. The oxygen in the ampoule is exhausted. After deoxygenation, quickly move the ampoule to the nozzle of the spray gun, and seal the ampoule with an outer flame. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacketed reaction flask is placed on the magnetic stirrer, at this time the temperature of the photothermal conversion is 60.0°C. After the reaction reaches a certain time, the ampoule is cooled down, the tube is broken, and the conversion rate is calculated by the gravimetric method. The structural formula of the product polymer PMMA prepared by the above method is as follows:

Table 7: Test results of "living" radical polymerization of bromine-iodine conversion

Table 7 shows the test results of the polymerization under the above conditions, R represents [MMA] ₀ /[EBPA] ₀ /[NaI] ₀ /[BNI] ₀ ; the monomer conversion rate (Conv.%) is calculated by the weight method; M _n,th represents the molecular weight calculated according to the formula M _n,th =M _EBP-I +[Monomer] ₀ /[EBPA] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w / M _n represents the molecular weight distribution.

The results show that the polymer obtained by the in-situ bromine-iodine conversion "living" radical polymerization method also has a controllable molecular weight and a narrow molecular weight distribution.

Example 9 Preparation of polymer PMMA by photothermal conversion of different croton acid cyanine dyes

In this example, the croconocyanine dyes represented by formulas (2) and (3) above in the specification of different structures were investigated in place of formula (1) for photothermal conversion. At this time, they also have high-efficiency photothermal conversion capabilities. Realize the "living" radical polymerization of vinyl monomers. Dissolve 35.0 mg of the ketone acid cyanine dyes represented by formulas (2) and (3) with two different structures in 7 mL of toluene solution, respectively, and transfer them to the designed device jacket, that is, the first cavity. A water bath environment is set in the inner layer of the glass jacketed reaction flask, in which an ampoule containing the reaction liquid (ie, the second cavity) is placed. The glass jacketed reaction flask was placed in the center of a near-infrared ring light source (λ=810nm, 100mW/cm ² ) in a ring shape, and the glass jacketed reaction flask was placed on a magnetic stirrer.

Among them, the preparation method of the reaction solution is as follows: the polymerization system monomer methyl methacrylate (MMA), RAFT reagent 4-cyano-4-(thiobenzoyl)pentanoic acid (CPADB) and the thermal initiator azo azobisisobutyronitrile (AIBN) at a molar ratio of _{[MMA] 0 / [CPADB]} 0 / [AIBN] 0 = 500/2/1, the MMA (0.20mL, 1.88mmol), CPADB (2.10mg, 7.53 × 10 - ³ mmol), AIBN (0.62mg, 3.76×10 ^-3 mmol), toluene (0.30mL), add to 2mL clean ampoule, put a clean stir bar. The mixed solution is a pink homogeneous solution. Place the ampoule in liquid nitrogen to freeze the solution, and then pump for 20-30 seconds, then add argon to thaw and dissolve at room temperature, and then freeze and pump. Thaw and inflate, this process is repeated three times to remove the oxygen in the ampoule. After deoxygenation, quickly move the ampoule to the nozzle of the spray gun, and seal the ampoule with an outer flame. Place the sealed ampoule in the inner water bath of the jacket of the glass jacket reaction flask, and then place the glass jacket reaction flask in the center of the ring-shaped near-infrared ring light source (λ=810nm, 100mW/cm ² ) , The glass jacketed reaction flask is placed on the magnetic stirrer, and the temperature of the light-to-heat conversion is shown in Table 8. After the reaction reaches a certain time, the ampoule is cooled down, the tube is broken, and 20 μL of the polymer solution is dissolved in CDCl ₃ with a pipette to perform a ¹ H NMR test, and the conversion rate is calculated. The structural formula of the product polymer PMMA prepared by the above method is the same as that in Example 1.

Table 8: Test results of product polymerization under light-to-heat conversion of different dyes

Table 8 shows the test results of product polymerization using crotonocyanine dyes of different structures for photothermal conversion and RAFT polymerization. R represents [MMA] ₀ /[CPADB] ₀ /[AIBN] ₀ ; monomer conversion rate (Conv %) is calculated from the hydrogen nuclear magnetic spectrum; T represents the temperature of the reaction liquid in the ampoule. M _n,th represents the molecular weight calculated according to the formula M _n,th =M _CPADB +[Monomer] ₀ /[CPADB] ₀ ×M _monomer ×Conv.(%); M _n,GPC represents the molecular weight obtained by GPC; M _w / M _n represents the molecular weight distribution.

It can be analyzed from Table 8 that crotonocyanine dyes (2) and (3) with different structures still have high photothermal conversion efficiency, and the device designed in the present invention can realize the conversion of vinyl monomers through photothermal conversion. "Living" free radical polymerization.

In the present invention, the polymerized monomers used can also be selected in addition to methyl methacrylate (MMA), methyl acrylate (MA), N,N-dimethylacrylamide (DMA), glycidyl methacrylate ( GMA) and other monomers other than styrene (St) such as butyl (meth)acrylate, polyethylene glycol monomethyl ether (meth)acrylate, hydroxyethyl (meth)acrylate, (methyl) Hydroxypropyl acrylate, N,N-dimethylaminoethyl (meth)acrylate, N,N-diethyl acrylamide, N-dihydroxyethyl acrylamide, etc. can also be "active" by the above polymerization method. /Controllable polymer.

In summary, the present invention utilizes the photothermal conversion characteristics of crotonic acid cyanine near-infrared dyes with different structures, and realizes the conversion of vinyl monomers through photothermal conversion under the irradiation of a near-infrared ring light source (λ=810nm). Living" free radical polymerization shows very good characteristics of "living"/controllable polymerization. For example, the conversion rate reaches 81.9% in 7 hours, and the molecular weight distribution is narrow (M _w /M _n <1.20). The GPC molecular weight of the obtained polymer is closer to the theoretical molecule, indicating that the polymer has a high degree of terminal functionalization. From the viewpoint of polymerization kinetics, it accords with the characteristics of first-order kinetics. By conducting chain extension experiments on low-molecular-weight polymers, high-molecular-weight polymers are obtained, which proves that the polymerization method is "living"/controllable radical polymerization.

The above are only the preferred embodiments of the present invention and are not intended to limit the present invention. It should be pointed out that for those of ordinary skill in the art, without departing from the technical principles of the present invention, several improvements and modifications can be made. These improvements and modifications should also be regarded as the protection scope of the present invention.

Claims

The "living" radical polymerization method of vinyl monomers under near-infrared photothermal conversion is characterized in that:

The reaction vessel is irradiated with near-infrared light with a wavelength of 750-850nm. The reaction vessel used has a first cavity and a second cavity that are not connected to each other. The first cavity contains a near-infrared light-responsive dye. Organic solution, the second cavity is used to place a closed reaction bottle containing the reaction solution; near-infrared light is irradiated into the first cavity, and the near-infrared light-responsive dye converts the near-infrared light into Heat energy, and heat the reaction liquid in the second cavity to 50-100°C, so that the vinyl monomers in the reaction liquid undergo "living" radical polymerization to obtain the polymerization shown in formulas (4)-(6) Thing

The near-infrared light-responsive dyes include one or more of the crotonic acid cyanine compounds represented by formulas (1)-(3):

Wherein, n 1 and n 2 are independently selected from 1-10;

The reaction solution includes vinyl monomers, organic solvents, ATRP initiators, ATRP ligands and ATRP catalysts; or

The reaction liquid includes vinyl monomers, organic solvents, RAFT reagents and thermal initiators; or

The reaction solution includes vinyl monomers, organic solvents, ATRP initiators and additives; the additives include organic amines and/or iodine-containing compounds;

The structural formulas of the polymers represented by formulas (4)-(6) are as follows:

Wherein, m 1 , m 2 and m 3 are independently selected from 10-300;

R 1 , R 1 ′ and R 1 ″ are each independently selected from isobutyl cyano group, 4-cyanovaleric acid group, 2-phenylacetate group or 2-isobutyric acid ethyl group;

R 2 , R 2 ′ and R 2 ″ are each independently selected from hydrogen or methyl;

R 3 , R 3 ′ and R 3 ″ are each independently selected from phenyl, 2-naphthyl, bromine, chlorine or iodine;

R 4 is selected from methyl, butyl, polyethylene glycol monomethyl ether, hydroxyethyl, hydroxypropyl or N,N-dimethylaminoethyl;

R 5 is selected from hydrogen, methyl, ethyl or hydroxymethyl;

R 6 is selected from hydrogen, methyl, ethyl or hydroxymethyl.
The "living" radical polymerization method according to claim 1, wherein the concentration of the near-infrared light-responsive dye in the organic solution of the near-infrared light-responsive dye is 1.0-10.0 mg/mL, and the near-infrared light-responsive dye is 1.0-10.0 mg/mL. The power of light is 0.05-1.0W/cm 2 .
The "living" radical polymerization method according to claim 1, wherein the vinyl monomer is methyl acrylate, methyl methacrylate, butyl acrylate, butyl methacrylate, polyethylene acrylate Glycol monomethyl ether ester, polyethylene glycol monomethyl ether methacrylate, hydroxyethyl acrylate, hydroxyethyl methacrylate, hydroxypropyl acrylate, hydroxypropyl methacrylate, N,N-methacrylate Dimethylaminoethyl, glycidyl methacrylate, styrene, N,N-dimethylacrylamide, N,N-diethylacrylamide, N-dihydroxyethylacrylamide.
The "living" radical polymerization method according to claim 1, wherein the ATRP initiator is ethyl 2-bromophenylacetate, ethyl 2-bromoisobutyrate, and 2-iodo-2-methyl One or more of propionitrile; the ATRP ligand is one or more of bipyridine, pentamethyldivinyltriamine, hexamethyltrivinyltetraamine and triphenylphosphine; The ATRP catalyst is one or more of CuBr, CuCl, FeBr 2 and FeCl 2.
The "living" radical polymerization method according to claim 1, wherein the RAFT reagent is isobutyronitrile dithionaphthoate or 4-cyano-4-(thiobenzoyl)valeric acid ; The thermal initiator is azobisisobutyronitrile and/or benzoyl peroxide.
The "living" radical polymerization method according to claim 1, wherein the additive is one or more of NaI, KI, triethylamine, triethanolamine and tetrabutylammonium iodide; The organic solvent is one or more of toluene, acetone, ethanol, methanol, N,N-dimethylformamide and dimethyl sulfoxide.
The "living" radical polymerization method according to claim 1, wherein the molar ratio of the vinyl monomer, RAFT reagent and thermal initiator is 50-1000:2:1-0.5; The molar ratio of the vinyl monomer, ATRP initiator, ATRP catalyst and ATRP ligand is 50-1000:1:0.01-1.5:0.3-4.5; the vinyl monomer, ATRP initiator and additive are The molar ratio is 50-1000:1:1-10.
The "living" radical polymerization method according to claim 1, wherein the concentration of the vinyl monomer in the reaction solution is 1.0-8.0 mol/L.
The "living" radical polymerization method according to claim 1, wherein the first cavity surrounds the outside of the second cavity, and the near-infrared light generating device surrounds the outside of the first cavity.
A polymerization reaction device under near-infrared photothermal conversion, characterized in that it comprises a reaction vessel for receiving near-infrared light irradiation, and the reaction vessel has a first cavity and a second cavity that are not connected to each other The first cavity contains an organic solution of a near-infrared light-responsive dye, and the second cavity contains a reaction bottle containing a reaction liquid; the near-infrared light is irradiated to the first cavity In the body, the near-infrared light-responsive dye converts the near-infrared light into heat energy, and heats the reaction liquid in the second cavity to 50-100°C.